/* FluidSynth - A Software Synthesizer
 *
 * Copyright (C) 2003  Peter Hanappe and others.
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Library General Public License
 * as published by the Free Software Foundation; either version 2 of
 * the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Library General Public License for more details.
 *
 * You should have received a copy of the GNU Library General Public
 * License along with this library; if not, write to the Free
 * Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
 * 02110-1301, USA
 */

/* Original author: Markus Nentwig, nentwig@users.sourceforge.net
 *
 * Josh Green made it general purpose with a complete usable public API and
 * cleaned it up a bit.
 */

#define FLUIDINC
#include "config.h"
#if !C_FLUIDSYNTH && defined(WIN32) && !defined(C_HX_DOS)
#include "fluid_midi_router.h"
#include "fluid_midi.h"
#include "fluid_synth.h"

/*
 * fluid_midi_router
 */
struct _fluid_midi_router_t {
  fluid_synth_t* synth;

  fluid_mutex_t rules_mutex;
  fluid_midi_router_rule_t *rules[FLUID_MIDI_ROUTER_RULE_COUNT];        /* List of rules for each rule type */
  fluid_midi_router_rule_t *free_rules;      /* List of rules to free (was waiting for final events which were received) */

  handle_midi_event_func_t event_handler;    /* Callback function for generated events */
  void* event_handler_data;                  /* One arg for the callback */

  int nr_midi_channels;                      /* For clipping the midi channel */

  /* FIXME - If there are multiple command handlers, they will conflict! */
  fluid_midi_router_rule_t *cmd_rule;        /* Rule currently being processed by shell command handler */
  int cmd_rule_type;                         /* Type of the rule (fluid_midi_router_rule_type) */
};

struct _fluid_midi_router_rule_t {
    int chan_min;                            /* Channel window, for which this rule is valid */
    int chan_max;
    fluid_real_t chan_mul;                   /* Channel multiplier (usually 0 or 1) */
    int chan_add;                            /* Channel offset */

    int par1_min;                            /* Parameter 1 window, for which this rule is valid */
    int par1_max;
    fluid_real_t par1_mul;
    int par1_add;

    int par2_min;                            /* Parameter 2 window, for which this rule is valid */
    int par2_max;
    fluid_real_t par2_mul;
    int par2_add;

    int pending_events;                      /* In case of noteon: How many keys are still down? */
    char keys_cc[128];                       /* Flags, whether a key is down / controller is set (sustain) */
    fluid_midi_router_rule_t* next;          /* next entry */
    int waiting;                             /* Set to TRUE when rule has been deactivated but there are still pending_events */
};


/**
 * Create a new midi router.  The default rules will pass all events unmodified.
 * @param settings Settings used to configure MIDI router
 * @param handler MIDI event callback.
 * @param event_handler_data Caller defined data pointer which gets passed to 'handler'
 * @return New MIDI router instance or NULL on error
 *
 * The MIDI handler callback should process the possibly filtered/modified MIDI
 * events from the MIDI router and forward them on to a synthesizer for example.
 * The function fluid_synth_handle_midi_event() can be used for \a handle and
 * a #fluid_synth_t passed as the \a event_handler_data parameter for this purpose.
 */
fluid_midi_router_t *
new_fluid_midi_router(fluid_settings_t *settings, handle_midi_event_func_t handler,
                      void *event_handler_data)
{
  fluid_midi_router_t *router = NULL;
  int i;

  router = FLUID_NEW (fluid_midi_router_t);

  if (router == NULL)
  {
    FLUID_LOG(FLUID_ERR, "Out of memory");
    return NULL;
  }

  FLUID_MEMSET (router, 0, sizeof (fluid_midi_router_t));

  /* Retrieve the number of MIDI channels for range limiting */
  fluid_settings_getint(settings, "synth.midi-channels", &router->nr_midi_channels);

  fluid_mutex_init (router->rules_mutex);

  router->synth = (fluid_synth_t *)event_handler_data;
  router->event_handler = handler;
  router->event_handler_data = event_handler_data;

  /* Create default routing rules which pass all events unmodified */
  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    router->rules[i] = new_fluid_midi_router_rule ();
    if (!router->rules[i]) goto error_recovery;
  }

  return router;

 error_recovery:
  delete_fluid_midi_router (router);
  return NULL;
}

/**
 * Delete a MIDI router instance.
 * @param router MIDI router to delete
 * @return Returns #FLUID_OK on success, #FLUID_FAILED otherwise (only if NULL
 *   \a router passed really)
 */
int
delete_fluid_midi_router (fluid_midi_router_t *router)
{
  fluid_midi_router_rule_t *rule;
  fluid_midi_router_rule_t *next_rule;
  int i;

  fluid_return_val_if_fail (router != NULL, FLUID_FAILED);

  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    for (rule = router->rules[i]; rule; rule = next_rule)
    {
      next_rule = rule->next;
      FLUID_FREE (rule);
    }
  }

  fluid_mutex_destroy (router->rules_mutex);
  FLUID_FREE (router);

  return FLUID_OK;
}

/**
 * Set a MIDI router to use default "unity" rules. Such a router will pass all
 * events unmodified.
 * @param router Router to set to default rules.
 * @return #FLUID_OK on success, #FLUID_FAILED otherwise
 * @since 1.1.0
 */
int
fluid_midi_router_set_default_rules (fluid_midi_router_t *router)
{
  fluid_midi_router_rule_t *new_rules[FLUID_MIDI_ROUTER_RULE_COUNT];
  fluid_midi_router_rule_t *del_rules[FLUID_MIDI_ROUTER_RULE_COUNT];
  fluid_midi_router_rule_t *rule, *next_rule, *prev_rule;
  int i, i2;

  fluid_return_val_if_fail (router != NULL, FLUID_FAILED);

  /* Allocate new default rules outside of lock */

  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    new_rules[i] = new_fluid_midi_router_rule ();

    if (!new_rules[i])
    { /* Free already allocated rules */
      for (i2 = 0; i2 < i; i2++)
        delete_fluid_midi_router_rule (new_rules[i]);

      return FLUID_FAILED;
    }
  }


  fluid_mutex_lock (router->rules_mutex);       /* ++ lock */

  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    del_rules[i] = NULL;
    prev_rule = NULL;

    /* Process existing rules */
    for (rule = router->rules[i]; rule; rule = next_rule)
    {
      next_rule = rule->next;

      if (rule->pending_events == 0)    /* Rule has no pending events? */
      { /* Remove rule from rule list */
        if (prev_rule) prev_rule->next = next_rule;
        else if (rule == router->rules[i]) router->rules[i] = next_rule;

        /* Prepend to delete list */
        rule->next = del_rules[i];
        del_rules[i] = rule;
      }
      else
      {
        rule->waiting = TRUE;          /* Pending events, mark as waiting */
        prev_rule = rule;
      }
    }

    /* Prepend new default rule */
    new_rules[i]->next = router->rules[i];
    router->rules[i] = new_rules[i];
  }

  fluid_mutex_unlock (router->rules_mutex);     /* -- unlock */


  /* Free old rules outside of lock */

  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    for (rule = del_rules[i]; rule; rule = next_rule)
    {
      next_rule = rule->next;
      FLUID_FREE (rule);
    }
  }

  return FLUID_OK;
}

/**
 * Clear all rules in a MIDI router. Such a router will drop all events until
 * rules are added.
 * @param router Router to clear all rules from
 * @return #FLUID_OK on success, #FLUID_FAILED otherwise
 * @since 1.1.0
 */
int
fluid_midi_router_clear_rules (fluid_midi_router_t *router)
{
  fluid_midi_router_rule_t *del_rules[FLUID_MIDI_ROUTER_RULE_COUNT];
  fluid_midi_router_rule_t *rule, *next_rule, *prev_rule;
  int i;

  fluid_return_val_if_fail (router != NULL, FLUID_FAILED);

  fluid_mutex_lock (router->rules_mutex);       /* ++ lock */

  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    del_rules[i] = NULL;
    prev_rule = NULL;

    /* Process existing rules */
    for (rule = router->rules[i]; rule; rule = next_rule)
    {
      next_rule = rule->next;

      if (rule->pending_events == 0)    /* Rule has no pending events? */
      { /* Remove rule from rule list */
        if (prev_rule) prev_rule->next = next_rule;
        else if (rule == router->rules[i]) router->rules[i] = next_rule;

        /* Prepend to delete list */
        rule->next = del_rules[i];
        del_rules[i] = rule;
      }
      else
      {
        rule->waiting = TRUE;           /* Pending events, mark as waiting */
        prev_rule = rule;
      }
    }
  }

  fluid_mutex_unlock (router->rules_mutex);     /* -- unlock */


  /* Free old rules outside of lock */

  for (i = 0; i < FLUID_MIDI_ROUTER_RULE_COUNT; i++)
  {
    for (rule = del_rules[i]; rule; rule = next_rule)
    {
      next_rule = rule->next;
      FLUID_FREE (rule);
    }
  }

  return FLUID_OK;
}

/**
 * Add a rule to a MIDI router.
 * @param router MIDI router
 * @param rule Rule to add (used directly and should not be accessed again following a
 *   successful call to this function).
 * @param type The type of rule to add (#fluid_midi_router_rule_type)
 * @return #FLUID_OK on success, #FLUID_FAILED otherwise (invalid rule for example)
 * @since 1.1.0
 */
int
fluid_midi_router_add_rule (fluid_midi_router_t *router, fluid_midi_router_rule_t *rule,
                            int type)
{
  fluid_midi_router_rule_t *free_rules, *next_rule;

  fluid_return_val_if_fail (router != NULL, FLUID_FAILED);
  fluid_return_val_if_fail (rule != NULL, FLUID_FAILED);
  fluid_return_val_if_fail (type >= 0 && type < FLUID_MIDI_ROUTER_RULE_COUNT, FLUID_FAILED);


  fluid_mutex_lock (router->rules_mutex);       /* ++ lock */

  /* Take over free rules list, if any (to free outside of lock) */
  free_rules = router->free_rules;
  router->free_rules = NULL;

  rule->next = router->rules[type];
  router->rules[type] = rule;

  fluid_mutex_unlock (router->rules_mutex);     /* -- unlock */


  /* Free any deactivated rules which were waiting for events and are now done */

  for (; free_rules; free_rules = next_rule)
  {
    next_rule = free_rules->next;
    FLUID_FREE (free_rules);
  }

  return FLUID_OK;
}

/**
 * Create a new MIDI router rule.
 * @return Newly allocated router rule or NULL if out of memory.
 * @since 1.1.0
 *
 * The new rule is a "unity" rule which will accept any values and wont modify
 * them.
 */
fluid_midi_router_rule_t *
new_fluid_midi_router_rule (void)
{
  fluid_midi_router_rule_t *rule;

  rule = FLUID_NEW (fluid_midi_router_rule_t);

  if (rule == NULL) {
    FLUID_LOG(FLUID_ERR, "Out of memory");
    return NULL;
  }

  FLUID_MEMSET (rule, 0, sizeof (fluid_midi_router_rule_t));

  rule->chan_min = 0;
  rule->chan_max = 999999;
  rule->chan_mul = 1.0;
  rule->chan_add = 0;
  rule->par1_min = 0;
  rule->par1_max = 999999;
  rule->par1_mul = 1.0;
  rule->par1_add = 0;
  rule->par2_min = 0;
  rule->par2_max = 999999;
  rule->par2_mul = 1.0;
  rule->par2_add = 0;

  return rule;
};

/**
 * Free a MIDI router rule.
 * @param rule Router rule to free
 * @since 1.1.0
 *
 * Note that rules which have been added to a router are managed by the router,
 * so this function should seldom be needed.
 */
void
delete_fluid_midi_router_rule (fluid_midi_router_rule_t *rule)
{
  fluid_return_if_fail (rule != NULL);
  FLUID_FREE (rule);
}

/**
 * Set the channel portion of a rule.
 * @param rule MIDI router rule
 * @param min Minimum value for rule match
 * @param max Maximum value for rule match
 * @param mul Value which is multiplied by matching event's channel value (1.0 to not modify)
 * @param add Value which is added to matching event's channel value (0 to not modify)
 * @since 1.1.0
 *
 * The \a min and \a max parameters define a channel range window to match
 * incoming events to.  If \a min is less than or equal to \a max then an event
 * is matched if its channel is within the defined range (including \a min
 * and \a max). If \a min is greater than \a max then rule is inverted and matches
 * everything except in *between* the defined range (so \a min and \a max would match).
 *
 * The \a mul and \a add values are used to modify event channel values prior to
 * sending the event, if the rule matches.
 */
void
fluid_midi_router_rule_set_chan (fluid_midi_router_rule_t *rule, int min, int max,
                                 float mul, int add)
{
  fluid_return_if_fail (rule != NULL);
  rule->chan_min = min;
  rule->chan_max = max;
  rule->chan_mul = mul;
  rule->chan_add = add;
}

/**
 * Set the first parameter portion of a rule.
 * @param rule MIDI router rule
 * @param min Minimum value for rule match
 * @param max Maximum value for rule match
 * @param mul Value which is multiplied by matching event's 1st parameter value (1.0 to not modify)
 * @param add Value which is added to matching event's 1st parameter value (0 to not modify)
 * @since 1.1.0
 *
 * The 1st parameter of an event depends on the type of event.  For note events
 * its the MIDI note #, for CC events its the MIDI control number, for program
 * change events its the MIDI program #, for pitch bend events its the bend value,
 * for channel pressure its the channel pressure value and for key pressure
 * its the MIDI note number.
 *
 * Pitch bend values have a maximum value of 16383 (8192 is pitch bend center) and all
 * other events have a max of 127.  All events have a minimum value of 0.
 *
 * The \a min and \a max parameters define a parameter range window to match
 * incoming events to.  If \a min is less than or equal to \a max then an event
 * is matched if its 1st parameter is within the defined range (including \a min
 * and \a max). If \a min is greater than \a max then rule is inverted and matches
 * everything except in *between* the defined range (so \a min and \a max would match).
 *
 * The \a mul and \a add values are used to modify event 1st parameter values prior to
 * sending the event, if the rule matches.
 */
void
fluid_midi_router_rule_set_param1 (fluid_midi_router_rule_t *rule, int min, int max,
                                   float mul, int add)
{
  fluid_return_if_fail (rule != NULL);
  rule->par1_min = min;
  rule->par1_max = max;
  rule->par1_mul = mul;
  rule->par1_add = add;
}

/**
 * Set the second parameter portion of a rule.
 * @param rule MIDI router rule
 * @param min Minimum value for rule match
 * @param max Maximum value for rule match
 * @param mul Value which is multiplied by matching event's 2nd parameter value (1.0 to not modify)
 * @param add Value which is added to matching event's 2nd parameter value (0 to not modify)
 * @since 1.1.0
 *
 * The 2nd parameter of an event depends on the type of event.  For note events
 * its the MIDI velocity, for CC events its the control value and for key pressure
 * events its the key pressure value.  All other types lack a 2nd parameter.
 *
 * All applicable 2nd parameters have the range 0-127.
 *
 * The \a min and \a max parameters define a parameter range window to match
 * incoming events to.  If \a min is less than or equal to \a max then an event
 * is matched if its 2nd parameter is within the defined range (including \a min
 * and \a max). If \a min is greater than \a max then rule is inverted and matches
 * everything except in *between* the defined range (so \a min and \a max would match).
 *
 * The \a mul and \a add values are used to modify event 2nd parameter values prior to
 * sending the event, if the rule matches.
 */
void
fluid_midi_router_rule_set_param2 (fluid_midi_router_rule_t *rule, int min, int max,
                                   float mul, int add)
{
  fluid_return_if_fail (rule != NULL);
  rule->par2_min = min;
  rule->par2_max = max;
  rule->par2_mul = mul;
  rule->par2_add = add;
}

/**
 * Handle a MIDI event through a MIDI router instance.
 * @param data MIDI router instance #fluid_midi_router_t, its a void * so that
 *   this function can be used as a callback for other subsystems
 *   (new_fluid_midi_driver() for example).
 * @param event MIDI event to handle
 * @return #FLUID_OK on success, #FLUID_FAILED otherwise
 *
 * Purpose: The midi router is called for each event, that is received
 * via the 'physical' midi input. Each event can trigger an arbitrary number
 * of generated events (one for each rule that matches).
 *
 * In default mode, a noteon event is just forwarded to the synth's 'noteon' function,
 * a 'CC' event to the synth's 'CC' function and so on.
 *
 * The router can be used to:
 * - filter messages (for example: Pass sustain pedal CCs only to selected channels)
 * - split the keyboard (noteon with notenr < x: to ch 1, >x to ch 2)
 * - layer sounds (for each noteon received on ch 1, create a noteon on ch1, ch2, ch3,...)
 * - velocity scaling (for each noteon event, scale the velocity by 1.27 to give DX7 users
 *   a chance)
 * - velocity switching ("v <=100: Angel Choir; V > 100: Hell's Bells")
 * - get rid of aftertouch
 * - ...
 */
int
fluid_midi_router_handle_midi_event (void* data, fluid_midi_event_t* event)
{
  fluid_midi_router_t* router = (fluid_midi_router_t *)data;
  fluid_midi_router_rule_t **rulep, *rule, *next_rule, *prev_rule = NULL;
  int event_has_par2 = 0; /* Flag, indicates that current event needs two parameters */
  int par1_max = 127;     /* Range limit for par1 */
  int par2_max = 127;     /* Range limit for par2 */
  int ret_val = FLUID_OK;

  int chan; /* Channel of the generated event */
  int par1; /* par1 of the generated event */
  int par2;
  int event_par1;
  int event_par2;
  fluid_midi_event_t new_event;

  /* Some keyboards report noteoff through a noteon event with vel=0.
   * Convert those to noteoff to ease processing. */
  if (event->type == NOTE_ON && event->param2 == 0)
  {
    event->type = NOTE_OFF;
    event->param2 = 127;        /* Release velocity */
  }

  fluid_mutex_lock (router->rules_mutex);   /* ++ lock rules */

  /* Depending on the event type, choose the correct list of rules. */
  switch (event->type)
  {
      case NOTE_ON:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_NOTE];
	event_has_par2 = 1;
	break;
      case NOTE_OFF:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_NOTE];
	event_has_par2 = 1;
	break;
      case CONTROL_CHANGE:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_CC];
	event_has_par2 = 1;
	break;
      case PROGRAM_CHANGE:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_PROG_CHANGE];
	break;
      case PITCH_BEND:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_PITCH_BEND];
	par1_max = 16383;
	break;
      case CHANNEL_PRESSURE:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_CHANNEL_PRESSURE];
	break;
      case KEY_PRESSURE:
	rulep = &router->rules[FLUID_MIDI_ROUTER_RULE_KEY_PRESSURE];
	event_has_par2 = 1;
	break;
      case MIDI_SYSTEM_RESET:
      case MIDI_SYSEX:
        ret_val = router->event_handler (router->event_handler_data,event);
        fluid_mutex_unlock (router->rules_mutex);  /* -- unlock rules */
        return ret_val;
      default:
        rulep = NULL;    /* Event will not be passed on */
	break;
  }

  /* Loop over rules in the list, looking for matches for this event. */
  for (rule = rulep ? *rulep : NULL; rule; prev_rule = rule, rule = next_rule)
  {
    event_par1 = (int)event->param1;
    event_par2 = (int)event->param2;
    next_rule = rule->next;     /* Rule may get removed from list, so get next here */

    /* Channel window */
    if (rule->chan_min > rule->chan_max)
    { /* Inverted rule: Exclude everything between max and min (but not min/max) */
      if (event->channel > rule->chan_max && event->channel < rule->chan_min)
	continue;
    }
    else        /* Normal rule: Exclude everything < max or > min (but not min/max) */
    {
      if (event->channel > rule->chan_max || event->channel < rule->chan_min)
	continue;
    }

    /* Par 1 window */
    if (rule->par1_min > rule->par1_max)
    { /* Inverted rule: Exclude everything between max and min (but not min/max) */
      if (event_par1 > rule->par1_max && event_par1 < rule->par1_min)
	continue;
    }
    else        /* Normal rule: Exclude everything < max or > min (but not min/max)*/
    {
      if (event_par1 > rule->par1_max || event_par1 < rule->par1_min)
	continue;
    }

    /* Par 2 window (only applies to event types, which have 2 pars)
     * For noteoff events, velocity switching doesn't make any sense.
     * Velocity scaling might be useful, though.
     */
    if (event_has_par2 && event->type != NOTE_OFF)
    {
      if (rule->par2_min > rule->par2_max)
      { /* Inverted rule: Exclude everything between max and min (but not min/max) */
	if (event_par2 > rule->par2_max && event_par2 < rule->par2_min)
	  continue;
      }
      else      /* Normal rule: Exclude everything < max or > min (but not min/max)*/
      {
	if (event_par2 > rule->par2_max || event_par2 < rule->par2_min)
	  continue;
      }
    }

    /* Channel scaling / offset
     * Note: rule->chan_mul will probably be 0 or 1. If it's 0, input from all
     * input channels is mapped to the same synth channel.
     */
    chan = (int)((fluid_real_t)event->channel * (fluid_real_t)rule->chan_mul
                 + (fluid_real_t)rule->chan_add + 0.5);

    /* Par 1 scaling / offset */
    par1 = (int)((fluid_real_t)event_par1 * (fluid_real_t)rule->par1_mul
                 + (fluid_real_t)rule->par1_add + 0.5);

    /* Par 2 scaling / offset, if applicable */
    if (event_has_par2)
      par2 = (int)((fluid_real_t)event_par2 * (fluid_real_t)rule->par2_mul
                   + (fluid_real_t)rule->par2_add + 0.5);
    else par2 = 0;

    /* Channel range limiting */
    if (chan < 0)
      chan = 0;
    else if (chan >= router->nr_midi_channels)
      chan = router->nr_midi_channels - 1;

    /* Par1 range limiting */
    if (par1 < 0)
      par1 = 0;
    else if (par1 > par1_max)
      par1 = par1_max;

    /* Par2 range limiting */
    if (event_has_par2)
    {
      if (par2 < 0)
        par2 = 0;
      else if (par2 > par2_max)
        par2 = par2_max;
    }

    /* At this point we have to create an event of event->type on 'chan' with par1 (maybe par2).
     * We keep track on the state of noteon and sustain pedal events. If the application tries
     * to delete a rule, it will only be fully removed, if pending noteoff / pedal off events have
     * arrived. In the meantime while waiting, it will only let through 'negative' events
     * (noteoff or pedal up).
     */
    if (event->type == NOTE_ON || (event->type == CONTROL_CHANGE
                                   && par1 == SUSTAIN_SWITCH && par2 >= 64))
    {
      /* Noteon or sustain pedal down event generated */
      if (rule->keys_cc[par1] == 0)
      {
	rule->keys_cc[par1] = 1;
	rule->pending_events++;
      }
    }
    else if (event->type == NOTE_OFF || (event->type == CONTROL_CHANGE
                                         && par1 == SUSTAIN_SWITCH && par2 < 64))
    { /* Noteoff or sustain pedal up event generated */
      if (rule->keys_cc[par1] > 0)
      {
	rule->keys_cc[par1] = 0;
	rule->pending_events--;

        /* Rule is waiting for negative event to be destroyed? */
        if (rule->waiting)
        {
	  if (rule->pending_events == 0)
          { /* Remove rule from rule list */
            if (prev_rule) prev_rule->next = next_rule;
            else *rulep = next_rule;

            /* Add to free list */
            rule->next = router->free_rules;
            router->free_rules = rule;

            rule = prev_rule;   /* Set rule to previous rule, which gets assigned to the next prev_rule value (in for() statement) */
          }

          goto send_event;      /* Pass the event to complete the cycle */
        }
      }
    }

    /* Rule is still waiting for negative event? (note off or pedal up) */
    if (rule->waiting)
      continue;         /* Skip (rule is inactive except for matching negative event) */

send_event:

    /* At this point it is decided, what is sent to the synth.
     * Create a new event and make the appropriate call */

    fluid_midi_event_set_type (&new_event, event->type);
    fluid_midi_event_set_channel (&new_event, chan);
    new_event.param1 = par1;
    new_event.param2 = par2;

    /* FIXME - What should be done on failure?  For now continue to process events, but return failure to caller. */
    if (router->event_handler (router->event_handler_data, &new_event) != FLUID_OK)
      ret_val = FLUID_FAILED;
  }

  fluid_mutex_unlock (router->rules_mutex);         /* -- unlock rules */

  return ret_val;
}

#define CHECK_VALID_ROUTER(_router, _out)                                                \
  if (router == NULL) {                                                                  \
    fluid_ostream_printf(out, "cannot execute router command without a midi router.\n"); \
    return FLUID_FAILED;                                                                 \
  }

/* Command handler for "router_clear" command */
int
fluid_midi_router_handle_clear (fluid_synth_t* synth, int ac, char** av,
                                fluid_ostream_t out)
{
  fluid_midi_router_t *router = synth->midi_router;

  if (ac != 0) {
    fluid_ostream_printf (out, "router_clear needs no arguments.\n");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  fluid_midi_router_clear_rules (router);

  return FLUID_OK;
}

/* Command handler for "router_default" command */
int
fluid_midi_router_handle_default(fluid_synth_t* synth, int ac, char** av, fluid_ostream_t out)
{
  fluid_midi_router_t *router = synth->midi_router;

  if (ac != 0) {
    fluid_ostream_printf(out, "router_default needs no arguments.\n");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  fluid_midi_router_set_default_rules (router);

  return FLUID_OK;
}

/* Command handler for "router_begin" command */
int
fluid_midi_router_handle_begin (fluid_synth_t* synth, int ac, char** av, fluid_ostream_t out)
{
  fluid_midi_router_t* router = synth->midi_router;

  if (ac != 1) {
    fluid_ostream_printf (out, "router_begin requires [note|cc|prog|pbend|cpress|kpress]\n");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  if (FLUID_STRCMP (av[0], "note") == 0)
    router->cmd_rule_type = FLUID_MIDI_ROUTER_RULE_NOTE;
  else if (FLUID_STRCMP (av[0], "cc") == 0)
    router->cmd_rule_type = FLUID_MIDI_ROUTER_RULE_CC;
  else if (FLUID_STRCMP (av[0], "prog") == 0)
    router->cmd_rule_type = FLUID_MIDI_ROUTER_RULE_PROG_CHANGE;
  else if (FLUID_STRCMP (av[0], "pbend") == 0)
    router->cmd_rule_type = FLUID_MIDI_ROUTER_RULE_PITCH_BEND;
  else if (FLUID_STRCMP (av[0], "cpress") == 0)
    router->cmd_rule_type = FLUID_MIDI_ROUTER_RULE_CHANNEL_PRESSURE;
  else if (FLUID_STRCMP (av[0], "kpress") == 0)
    router->cmd_rule_type = FLUID_MIDI_ROUTER_RULE_KEY_PRESSURE;
  else
  {
    fluid_ostream_printf (out, "router_begin requires [note|cc|prog|pbend|cpress|kpress]\n");
    return FLUID_FAILED;
  }

  if (router->cmd_rule)
    delete_fluid_midi_router_rule (router->cmd_rule);

  router->cmd_rule = new_fluid_midi_router_rule ();

  if (!router->cmd_rule)
    return FLUID_FAILED;

  return FLUID_OK;
}

/* Command handler for "router_end" command */
int
fluid_midi_router_handle_end (fluid_synth_t* synth, int ac, char** av,
                              fluid_ostream_t out)
{
  fluid_midi_router_t* router = synth->midi_router;

  if (ac != 0) {
    fluid_ostream_printf (out, "router_end needs no arguments.\n");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  if (!router->cmd_rule)
  {
    fluid_ostream_printf (out, "No active router_begin command.\n");
    return FLUID_FAILED;
  }

  /* Add the rule */
  if (fluid_midi_router_add_rule (router, router->cmd_rule, router->cmd_rule_type) != FLUID_OK)
    delete_fluid_midi_router_rule (router->cmd_rule);   /* Free on failure */

  router->cmd_rule = NULL;

  return FLUID_OK;
}

/* Command handler for "router_chan" command */
int
fluid_midi_router_handle_chan (fluid_synth_t* synth, int ac, char** av,
                               fluid_ostream_t out)
{
  fluid_midi_router_t* router = synth->midi_router;

  if (ac != 4) {
    fluid_ostream_printf(out, "router_chan needs four args: min, max, mul, add.");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  if (!router->cmd_rule)
  {
    fluid_ostream_printf (out, "No active router_begin command.\n");
    return FLUID_FAILED;
  }

  fluid_midi_router_rule_set_chan (router->cmd_rule, atoi (av[0]), atoi (av[1]),
                                   (float)atof (av[2]), atoi (av[3]));
  return FLUID_OK;
}

/* Command handler for "router_par1" command */
int
fluid_midi_router_handle_par1 (fluid_synth_t* synth, int ac, char** av, fluid_ostream_t out)
{
  fluid_midi_router_t* router = synth->midi_router;

  if (ac != 4) {
    fluid_ostream_printf(out, "router_par1 needs four args: min, max, mul, add.");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  if (!router->cmd_rule)
  {
    fluid_ostream_printf (out, "No active router_begin command.\n");
    return FLUID_FAILED;
  }

  fluid_midi_router_rule_set_param1 (router->cmd_rule, atoi (av[0]), atoi (av[1]),
                                     (float)atof (av[2]), atoi (av[3]));
  return FLUID_OK;
}

/* Command handler for "router_par2" command */
int
fluid_midi_router_handle_par2 (fluid_synth_t* synth, int ac, char** av,
                               fluid_ostream_t out)
{
  fluid_midi_router_t* router = synth->midi_router;

  if (ac != 4) {
    fluid_ostream_printf(out, "router_par2 needs four args: min, max, mul, add.");
    return FLUID_FAILED;
  }

  CHECK_VALID_ROUTER (router, out);

  if (!router->cmd_rule)
  {
    fluid_ostream_printf (out, "No active router_begin command.\n");
    return FLUID_FAILED;
  }

  fluid_midi_router_rule_set_param2 (router->cmd_rule, atoi (av[0]), atoi (av[1]),
                                     (float)atof (av[2]), atoi (av[3]));
  return FLUID_OK;
}

/**
 * MIDI event callback function to display event information to stdout
 * @param data MIDI router instance
 * @param event MIDI event data
 * @return #FLUID_OK on success, #FLUID_FAILED otherwise
 *
 * An implementation of the #handle_midi_event_func_t function type, used for
 * displaying MIDI event information between the MIDI driver and router to
 * stdout.  Useful for adding into a MIDI router chain for debugging MIDI events.
 */
int fluid_midi_dump_prerouter(void* data, fluid_midi_event_t* event)
{
  switch (event->type) {
      case NOTE_ON:
	fprintf(stdout, "event_pre_noteon %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      case NOTE_OFF:
	fprintf(stdout, "event_pre_noteoff %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      case CONTROL_CHANGE:
	fprintf(stdout, "event_pre_cc %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      case PROGRAM_CHANGE:
	fprintf(stdout, "event_pre_prog %i %i\n", event->channel, event->param1);
	break;
      case PITCH_BEND:
        fprintf(stdout, "event_pre_pitch %i %i\n", event->channel, event->param1);
	break;
      case CHANNEL_PRESSURE:
	fprintf(stdout, "event_pre_cpress %i %i\n", event->channel, event->param1);
	break;
      case KEY_PRESSURE:
	fprintf(stdout, "event_pre_kpress %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      default:
	break;
  }
  return fluid_midi_router_handle_midi_event((fluid_midi_router_t*) data, event);
}

/**
 * MIDI event callback function to display event information to stdout
 * @param data MIDI router instance
 * @param event MIDI event data
 * @return #FLUID_OK on success, #FLUID_FAILED otherwise
 *
 * An implementation of the #handle_midi_event_func_t function type, used for
 * displaying MIDI event information between the MIDI driver and router to
 * stdout.  Useful for adding into a MIDI router chain for debugging MIDI events.
 */
int fluid_midi_dump_postrouter(void* data, fluid_midi_event_t* event)
{
  switch (event->type) {
      case NOTE_ON:
	fprintf(stdout, "event_post_noteon %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      case NOTE_OFF:
	fprintf(stdout, "event_post_noteoff %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      case CONTROL_CHANGE:
	fprintf(stdout, "event_post_cc %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      case PROGRAM_CHANGE:
	fprintf(stdout, "event_post_prog %i %i\n", event->channel, event->param1);
	break;
      case PITCH_BEND:
	fprintf(stdout, "event_post_pitch %i %i\n", event->channel, event->param1);
	break;
      case CHANNEL_PRESSURE:
	fprintf(stdout, "event_post_cpress %i %i\n", event->channel, event->param1);
	break;
      case KEY_PRESSURE:
	fprintf(stdout, "event_post_kpress %i %i %i\n",
		event->channel, event->param1, event->param2);
	break;
      default:
	break;
  }
  return fluid_synth_handle_midi_event((fluid_synth_t*) data, event);
}
#endif